DE3307003C2 - - Google Patents

Description

There are already safety ski bindings with electronic release systems known the z. B. in the event of malfunction or failure the triggering properties of a mechanical, maintain binding working with a release spring. In DE-OS 30 17 841 describes such a bond, which works that a mechanical, hydraulic or pneumatic emergency release system in the event of failure of the electrical control to the Place of this system occurs while the trigger system is in use normal functioning, in which the electrical control is used will not work. Since the regulation of each of the two systems that are in parallel are connected to each other, takes place completely independently, the Skiers run the risk of failing during an electronic Systems compared to the values shortly before the failure find different trigger values. This situation is for them Safety of the skier extremely disadvantageous, which suddenly changes skiing conditions exposed who do not meet his expectations. In the well-known ski binding is not one in one cheek housed release spring worked, but the connection of Ski boot and ski takes place in such a way that in the longitudinal direction of the ski arranged axes swiveling side holding jaws with on the ski boot attached, laterally projecting pin interact.

A ski binding is known to be known from DE-OS 27 36 027, in the case of which loads were determined exclusively by electrical means  and processed, then an electrical trigger circuit to operate. The electronic circuit therefore acts directly on the Trigger on.

DE-OS 24 08 419 is about a delay device to create a ski binding that inhibits triggering in the case of harmless bumps and still a quick return of the the binding parts holding the shoe are guaranteed in the position of use. The trigger spring is coupled to a pneumatic system, which acts like a shock absorber to prevent the movement of a Delay piston in the release of the bond. An influence the setting of the shock absorber is not provided, and also there is no electronic circuit.

The invention has for its object to provide a ski safety binding To make available where the regulation of the release force is perfected and the optimal reluctance to trigger in Dependence on the ski conditions is guaranteed.

The solution to this problem is with those specified in claim 1 Characteristics achieved.

The basic idea of the invention is that a restraining force basically exists and only that depending on a fall occurring, differently large disturbing forces by means of the with the Trigger spring constantly interacting mechanical, hydraulic or pneumatic system acting electronic circuit balanced will. The one consisting of the release spring and the additional system Release system has a certain retention force due to high interference forces is designed in the form of frictional forces. With low frictional forces  the bond can absorb the difference in force without triggering to have to. The always present retention force of the release spring is supplemented by the variable forces exerted by the additional system, which is a minimum in a driving accident and a maximum in reporting of the ski boot in the binding. The additional system provides something like one through the electrical circuit in its effect adjustable shock absorber. In the event of a possible failure of the electronic Switching is the trigger function solely through the trigger spring guaranteed.

Advantageous further embodiments of the security binding are Subject matter of claims 2 and 3.

The invention is illustrated below with reference to the drawing Embodiments explained in more detail. It shows or show:  

Fig. 1 is a partially sectioned plan view of a Skibindungsbacken which is provided with a hydraulic release support system which is controlled by an electric circuit,

FIG. 2 shows an enlarged illustration of a detail according to circle II in FIG. 1.

Fig. 3 is a partial sectional view according to section line III-III in Fig. 2,

Fig. 4 and 5 of Fig. 2 corresponding representation of the hydraulic piston during normal skiing,

Fig. 6 is a schematic sectional view of another hydraulic support system which is realized on the basis of a membrane means,

FIGS. 7 and 8 are cross sectional views of the various opening positions of the diaphragm in accordance with the electrical excitations

Fig. 9 is a partially sectioned plan view of a modified binding baking, wherein the support system is electro-mechanically,

In which is shown by the electro-mechanical support system for a given electrical energization position occupied Fig. 10 a of FIG. 9 corresponding representation,

Fig. 11 is a longitudinal sectional view of another embodiment in which the electro-mechanical support system is arranged in the sole of the boot, while the main tripping device remains in the bindings, and

Figs. 12 to 14, the operation of the embodiment of Figure 11 for various load conditions electric Fig..

In Fig. 1 a first embodiment is shown with a Skibindungsvorderbacken 1 in which a trigger support system is arranged.

This system is arranged parallel to the release spring 2 of a main piston 3 which, as is known, is accommodated in a rotating body 4 which is mounted about an axis 6 which is provided with a flattened portion 5 . In the footrest plate 7 , a sensor 8 is provided for vertical forces of the toe downward (case forward), while another sensor 9 is arranged in a sole holder 10 such that the vertical forces are upward (case backward) from the binding be taken into account. These sensors 8 , 9 are connected to a power source 11 and electronic circuits which transmit signals to a solenoid coil 12 which acts on a plunger 13 . The plunger is part of a hydraulic mechanism 14 with a hydraulic circuit 15 which connects two chambers 16 , 17 communicating with one another. The chamber 17 receives one end 3 'of the main trigger piston 3 , while the other end 3 ''cooperates with the flattened portion 5 of the axis 6 under the action of the trigger spring 2 . The end 3 'of the main piston 3 , which is arranged in the main chamber 17 of the hydraulic mechanism, is provided with a sliding plug 18 which is in the chamber 17 under the action of rotation of the toe 1 , z. B. due to a lateral impact. The cross section of the chamber 17 is larger than that of the chamber 16 . The cross-sectional difference leads to a braking of the fluid flow in the circuit, and a braking force is therefore caused which in particular opposes a displacement of the main piston 3 .

In order to change the use value of the device, it is provided to provide the plug 18 with an adjustable anti-return valve 20 in such a way that the fluid flow is more or less slowed down. For the sake of simplicity, the valve is only shown schematically in FIG. 1.

If a boot is not shown in the binding, the coil 12 is not under tension and the plunger 13 is maximally returned under the action of a return spring 19 ( FIGS. 2 and 3) such that the channel cross section S of the fluid in the chamber 16 is maximum.

No effect is detectable in the area of the hydraulic mechanism 14 and there is only a minimal retention force in addition to the retention force which is given by the release spring 2 .

If a boot is detected in the binding, the electrical circuit is energized. A current of size I then passes through the coil 12 . This acts on the plunger 13 , which advances a distance d in the chamber 16 , which leads to a reduction in the channel cross section S of the fluid flow ( FIGS. 4 and 5). This reduction in cross-section causes an increase in the retention force compared to the release, and this now corresponds to a preselected reference regulation value.

In the event of a driving accident which generates disruptive forces in the area of the sole of the boot and the footrest plate, these disruptive forces are indicated by one of the sensors 8 , 9 ; the current source 11 now sends only a current i₁ I in the coil 12 , such that the plunger 13 is returned by the return spring 19 . The channel cross section of the fluid increases again and the retention force decreases. If for some reason the electronic circuit fails, the coil 12 would no longer be supplied with power and the plunger 13 would be returned as far as possible in its cylinder 21 , as a result of which the cross section of the fluid channel would be returned to its initial value S. As a result, the skier finds a release retention value which corresponds to the minimum conditions for skiing, which he has determined by regulating the release spring 2 . Nevertheless, the coupling of the hydraulic device to the main spring in the event of shocks and even in the event of failure of the electronics allows a momentary increase in the retention value compared to the triggering or the trigger retention value due to the fact that for a given cross section of the fluid channel through the on the main piston the flattening force exerted is much greater when the displacement speed is fast. The trigger retention value for impacts increases directly depending on the displacement speeds of the jaws.

Another hydraulic support system is shown in FIGS. 6 to 8, the operation of which is similar to the previous one. A bellows membrane 22 is coupled to the release spring 23 of a piston 24 of a binding 25, which is not shown in full. The bellows membrane 22 has a first main bellows 26 , in the interior of which the release spring 23 is arranged, the outer side 27 of one of the ends of the bellows being supported in the interior of the piston 24 , which cooperates with the flat 28 on a fixed axis 29 of a jaw. The other end of the bellows 26 is tightly connected to a carrier 30 which is displaceable in the longitudinal direction of the jaw, in such a way that the tension of the main spring can be regulated. This carrier is provided with openings 31 which allow fluid flow between the main bellows 26 and the secondary bellows 32 , which is arranged on the other side of the carrier 30 . The bellows 32 is arranged in the interior of an adjusting screw plug 33 , which is supported on a closure ring 34 of the diaphragm. The rear end 35 of the bellows 32 is tightly connected to the ring. This closure ring is provided with the same number of openings 36 as the carrier 30 and rotatable about a circular bearing 37 , which also has openings corresponding to the openings of the carrier with which it is integrally formed ( Fig. 6).

If no boot is indicated in the binding, a coil 38 , which is intended to act on a control pin 39 , which is arranged approximately radially to the circular ring 34 ( FIGS. 7, 8), is not excited by a current and the openings 31 and 36 are fully aligned such that the fluid can flow from one bellows to another without obstruction. A return spring 40 keeps the locking annulus 34 constantly in contact with the control pin 39 , whatever the position of that pin. When the buckle is displayed, the electronics 41 and also the coil 38 are energized; the control pin 39 is retracted so far that the circular ring 34 performs a rotation along the arrow 42 under the action of the return spring 40 . As a result of this rotation, the cross section of the fluid channel ( FIG. 8) is reduced from one bellows to another and consequently the restraining force with respect to the release is increased, this corresponding to a preselected reference control. In this embodiment, the support system also advantageously enables regulation and damping of the triggering forces to be achieved due to impacts that can occur during skiing.

According to a third embodiment, shown in FIGS. 9 and 10, two springs 43 , 44 are provided for the release, which work in parallel in a binding jaw, the support system being of an electromechanical nature. The main spring 43 , which is supported on the one hand on a piston 45 and on the other hand on the body 46 of the jaw with the interposition of a sleeve 47 , which in turn is supported on the adjusting screw plug, is mounted parallel to a second spring 44 . This spring 44 is also supported on the one hand on the bottom of the piston 45 and on the other hand on a second piston 48 which is arranged in the sleeve 47 , where it is controlled by a knee joint system 49 . An electromagnetic device 50 is provided to act on the toggle system in accordance with the magnitude of a current generated by an electronic circuit 51 based on signals emitted by sensors 52 , 53 , respectively on the sole holder and the footrest plate of the jaw are arranged. Depending on the magnitude of the current flowing through the electromagnet 50 , the second spring 44 is more or less loaded depending on the displacement of the second piston 48 out of the sleeve ( FIG. 10).

If the electronic circuit 51 fails , the toggle lever 49 is automatically pushed back by the second spring and returns to the stop with the sleeve. There is now a trigger retention force that meets the minimum requirements for skiing. In this embodiment, the support from the electronics remains proportional to the control values of the trigger spring.

In Figs. 11 to 14, an embodiment is shown in which the trigger modulation system 54 is no longer in the jaws 55 a bond is located, but in the sole 56 of a boot, which cooperates with the jaws. 55 For this purpose, the jaws having a guiding or Mitnehmerkammer 57 for receiving a control pin 58, its penetration d₁ changed in the chamber, the length of the lever arm, which is formed by the contact point of the pin 58 and the axis 59 of the baking. On the other hand, the penetration is controlled by a toggle lever system 60 , which is arranged in the sole of the boot and is acted upon by one or more electromagnets 61 , 61 ′, 61 ′ ′, which receive signals which are emitted by sensors 62 , 63 , 64 , which are arranged in the Schlenhalterung and the footrest plate of the cheek.

The change in the lever arm has the consequence that the retaining ties of the lateral releases are changed. If the boots do not indicate the vicinity of a jaw, the coils of the electromagnets 61 , 61 ', 61 ''are not energized, and the control pin 58 is returned from the chamber 57 under the action of the return spring 65 . If the boot indicates the presence of the baking (while buckling up), an electronic computer 66 controls the penetration of the pin 58 with the interposition of the electromagnets 61 , 61 ', 61 ''. The lever arm d₁, which is determined by the distance of the axis 59 from the pin 58 , decreases to d₂. This gives a release retention force that corresponds to a preselected reference control ( FIG. 13).

Interference forces are displayed by sensors 62 , 63 , 64 . The presence of these interfering forces is transmitted by signals to the electronic computer, which sends a current of reduced size into the coils of the electromagnets 61 , 61 ', 61 ''. The return spring 65 guides the pin 58 backwards, thereby increasing the lever arm between d₂ and d₁ and consequently reducing the trigger retention force.

If the electronic circuit fails, the above-mentioned phenomenon increases, since the electromagnets are no longer energized and the control pin is completely returned to the rear under the action of the return spring 65 , which acts on the toggle lever system. The release retention force now corresponds to the minimum conditions for skiing and is realized by the retention force of the only main release spring 67 of the jaw.

The above-mentioned embodiments are described in connection with front binding jaws been. The present invention is of course also based on Binding back jaws applicable.

Claims (3)

1. Safety ski binding with a release spring ( 2 ) and with the release spring ( 2 ) constantly interacting mechanical, hydraulic or pneumatic system ( 14 ), the predetermined behavior of which can be varied by an electronic circuit which responds to signals from at least one between the Boots and the binding arranged load sensors ( 8 , 9 , 52 , 53 , 62 , 63 , 64 ) are delivered. 2. Safety ski binding according to claim 1, characterized in that the additional force of the mechanical, hydraulic or pneumatic system is greatest when the boot is inserted into the binding by the electronic circuit and by the sensor or sensors ( 8 , 9 , 52 , 53 ) displayed increasing interference is reduced. 3. Safety ski binding according to claim 1 or claim 2, characterized in that the mechanical, hydraulic or pneumatic system ( 54 ) is arranged in the sole of the boot and cooperates with the sole holder of the binding.